阅读说明：本技术 一种基于Revit的电气系统图生成方法 (Revit-based electric system diagram generation method ) 是由 张陆陆 张东升 刘建 牛传奇 卫界岑 于 2021-01-22 设计创作，主要内容包括：本发明涉及一种基于Revit的电气系统图生成方法,包括以下步骤：S1：对电气系统图进行区块划分,确认绘制内容的标准化模块划分；S2：建立标准化模块,确认各标准化模块中的子模块和子模块参数；S3：根据要绘制的电气系统图选取相应的标准化模块进行可见性拼合,形成初步电气系统图；S4：对初步电气系统图进行参数化计算,获取参数结果；S5：根据参数结果对初步系统图中的子模块参数进行修改；S6：完善电气系统图的标注信息,生成电气系统图。与现有技术相比,本发明基于对标准化模块的建立、拼合、计算和调整,能够标准化、模块化、规范化的生成电气系统,适用范围广,绘制效率高,满足标准化绘图的需求。(The invention relates to an electrical system diagram generation method based on Revit, which comprises the following steps: s1: dividing the electrical system diagram into blocks, and confirming the division of a standard module of the drawing content; s2: establishing standardized modules, and confirming sub-modules and sub-module parameters in each standardized module; s3: selecting corresponding standardized modules according to an electrical system diagram to be drawn to carry out visibility splicing to form a preliminary electrical system diagram; s4: carrying out parametric calculation on the preliminary electrical system diagram to obtain a parameter result; s5: modifying sub-module parameters in the primary system diagram according to the parameter result; s6: and perfecting the labeled information of the electrical system diagram to generate the electrical system diagram. Compared with the prior art, the method and the device have the advantages that based on the establishment, the splicing, the calculation and the adjustment of the standardized modules, the electric system can be generated in a standardized, modularized and normalized mode, the application range is wide, the drawing efficiency is high, and the requirement of standardized drawing is met.)

1. A method for generating an electrical system diagram based on Revit is characterized by comprising the following steps:

s1: dividing the electrical system diagram into blocks, and confirming the division of a standard module of the drawing content;

s2: establishing standardized modules, and confirming sub-modules and sub-module parameters in each standardized module;

s3: selecting corresponding standardized modules according to an electrical system diagram to be drawn to carry out visibility splicing to form a preliminary electrical system diagram;

s4: carrying out parametric calculation on the preliminary electrical system diagram to obtain a parameter result;

s5: modifying sub-module parameters in the primary system diagram according to the parameter result;

s6: and perfecting the labeled information of the electrical system diagram to generate the electrical system diagram.

2. The method for generating an electrical system diagram based on Revit according to claim 1, wherein the standardized modules comprise a single-incoming-line bus side module, a double-incoming-line bus side module, a loop side module, an emergency lighting centralized power supply module, an electric meter box module and a box body grounding module.

3. The method for generating an electrical system diagram based on Revit according to claim 2, wherein the step S3 specifically includes:

s31: selecting one bus side module as an electrical system diagram from the single-incoming-line bus side module and the double-incoming-line bus side module;

s32: selecting at least one module from the loop side module and the emergency lighting centralized power supply module as the loop side module of the electrical system diagram;

s33: and selecting one electric meter box module and one box body grounding module to be combined with the modules selected in S31 and S32 in a visibility mode to form a preliminary electric system diagram.

4. The method for generating an electrical system diagram based on Revit according to claim 1, wherein S6 specifically includes: the system header and the dashed line dividing box of the electrical system diagram are added to generate the electrical system diagram.

5. The Revit-based electrical system diagram generation method of claim 2, wherein the single incoming bus side module comprises a box information submodule, a power distribution calculation submodule, an incoming line description submodule, an incoming line switch model submodule, an electrical fire monitoring submodule, a transformer submodule and an overcurrent protection submodule.

6. The Revit-based electric system diagram generation method according to claim 2, wherein the loop side module comprises a loop matching phase sub-module, a switch type selection sub-module, a reservation sub-module, a loop numbering sub-module, a lead type selection sub-module, a loop load sub-module, a loop name sub-module, a fan control sub-module and an intelligent lighting sub-module.

7. The Revit-based electrical system diagram generation method of claim 2, wherein the electrical meter box module is an immutable module, and parameters of the electrical meter box module are not alterable.

8. The Revit-based electrical system diagram generation method of claim 2, wherein the box grounding module is an unchangeable module, and parameters of the electricity meter box module are unchangeable.

9. The Revit-based electric system diagram generation method of claim 2, wherein the double-incoming-line bus side module comprises an incoming line common and standby loop information submodule, a fire power supply monitoring submodule, a box body information submodule, a power distribution calculation submodule, an incoming line description submodule, an incoming line switch model submodule, an electric fire monitoring submodule, a mutual inductor submodule and an overcurrent protection submodule.

10. The method for generating an electrical system diagram based on Revit according to claim 2, wherein the emergency lighting centralized power supply module comprises a circuit matching phase sub-module, a switch selection sub-module, an eight-circuit emergency lighting power supply and outlet sub-module, an emergency lighting circuit sub-module, a circuit numbering sub-module, a lead selection sub-module, a circuit load sub-module and a circuit name sub-module.

Technical Field

The invention relates to an electric system diagram generation method, in particular to an electric system diagram generation method based on Revit.

Background

When the existing electrical system diagram is drawn, a plane drawing method is often adopted in three-dimensional modeling software, the electrical system diagram is drawn manually, then parameter design is carried out, finally a drawing is generated, drawing work is separated from design work, and the efficiency is low. Various parameters such as system components, switch model selection, wire model selection and the like are manually input, and model selection and calculation are generally performed in various tables summarized by other designers, so that the generation and drawing of an electric system drawing are separated from the model selection and design procedures of the electric system, the drawing efficiency is low, and the requirement of standardized drawing cannot be met.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide an electrical system diagram generation method based on Revit.

The purpose of the invention can be realized by the following technical scheme:

a Revit-based electrical system diagram generation method comprises the following steps:

s1: dividing the electrical system diagram into blocks, and confirming the division of a standard module of the drawing content;

s2: establishing standardized modules, and confirming sub-modules and sub-module parameters in each standardized module;

s3: selecting corresponding standardized modules according to an electrical system diagram to be drawn to carry out visibility splicing to form a preliminary electrical system diagram;

s4: carrying out parametric calculation on the preliminary electrical system diagram to obtain a parameter result;

s5: modifying sub-module parameters in the primary system diagram according to the parameter result;

s6: and perfecting the labeled information of the electrical system diagram to generate the electrical system diagram.

Preferably, the standardized modules comprise a single-incoming-line bus side module, a double-incoming-line bus side module, a loop side module, an emergency lighting centralized power module, an electric meter box module and a box body grounding module.

Preferably, the step S3 specifically includes:

s31: selecting one bus side module as an electrical system diagram from the single-incoming-line bus side module and the double-incoming-line bus side module;

s32: selecting at least one module from the loop side module and the emergency lighting centralized power supply module as the loop side module of the electrical system diagram;

s33: and selecting one electric meter box module and one box body grounding module to be combined with the modules selected in S31 and S32 in a visibility mode to form a preliminary electric system diagram.

Preferably, the S6 specifically includes: the system header and the dashed line dividing box of the electrical system diagram are added to generate the electrical system diagram.

Preferably, the single incoming line bus side module comprises a box body information submodule, a power distribution calculation submodule, an incoming line description submodule, an incoming line switch model submodule, an electrical fire monitoring submodule, a transformer submodule and an overcurrent protection submodule.

Preferably, the parameters of the box information submodule include bin number, size and installation mode, and the parameters of the power distribution calculation submodule include active power Pe, simultaneous coefficient Kc and power factorCalculating current Ic, wherein the parameters of the incoming line description submodule comprise an incoming line loop number, an incoming line cable model and an incoming line source, the parameters of the incoming line switch model submodule comprise an incoming line switch model and a corresponding graphic expression, the parameters of the electrical fire monitoring submodule comprise the existence/nonexistence and a mutual inductor model, and the parameters of the over-current protection submodule comprise the existence/nonexistence and the over-current protection device model.

Preferably, the loop side module comprises a loop matching phase submodule, a switch type selection submodule, a reserved submodule, a loop numbering submodule, a lead type selection submodule, a loop load submodule, a loop name submodule, a fan control submodule and an intelligent lighting submodule.

Preferably, the parameter of the loop phase matching submodule is a power supply phase, the parameter of the switch type selection submodule is a model number and a graphic expression, the parameter of the reserved submodule is presence/absence, the parameter of the loop number submodule is a loop number, the parameter of the lead type selection submodule is a lead model number, the parameter of the loop load submodule is a load size, the parameter of the loop name submodule is a loop name, and the parameter of the fan control submodule is presence/absence.

Preferably, the electric meter box module is an unchangeable module, and parameters of the electric meter box module are unchangeable.

Preferably, the box body grounding module is an invariable module, and the parameters of the electric meter box module are unchangeable.

Preferably, the double-incoming-line bus side module comprises an incoming line common and standby loop information submodule, a fire-fighting power supply monitoring submodule, a box body information submodule, a power distribution calculation submodule, an incoming line description submodule, an incoming line switch model submodule, an electrical fire monitoring submodule, a mutual inductor submodule and an overcurrent protection submodule.

Preferably, the parameters of the incoming line common and standby loop information submodule include a common loop number and a standby loop number, and the parameters of the fire-fighting power supply monitoring submodule are present or absent.

Preferably, the emergency lighting centralized power supply module comprises a loop phase matching sub-module, a switch type selection sub-module, an eight-loop emergency lighting power supply and outlet sub-module, an emergency lighting loop sub-module, a loop numbering sub-module, a lead type selection sub-module, a loop load sub-module and a loop name sub-module.

Preferably, the eight-loop emergency lighting power supply and the outgoing line sub-module are invariable modules, and parameters are not modifiable.

Compared with the prior art, the invention has the following advantages:

(1) the electric system diagram generation method is based on the establishment, splicing, calculation and adjustment of the standardized modules, can generate the electric system in a standardized, modularized and standardized manner, has wide application range and high drawing efficiency, and meets the requirement of standardized drawing;

(2) the power distribution parameter calculation of the invention is calculated and modified in the module, and the two procedures are combined for processing, so that the standardized drawing and parameter design can be simultaneously carried out on the electrical system diagram, and the drawing efficiency and the drawing accuracy are effectively improved;

(3) according to the invention, the standardized module is established, so that designers can select and combine the standardized module according to the requirement of designing the electrical system diagram, and perform parameter calculation and filling based on the preliminary electrical system diagram of the selected and combined module, thereby greatly reducing the design difficulty and improving the design accuracy and the working efficiency.

Drawings

FIG. 1 is a flow chart of the present invention;

FIG. 2 is a schematic diagram of an electrical system diagram generated by the present invention;

FIG. 3 is a schematic diagram of a single incoming busbar side module of the present invention;

FIG. 4 is a schematic diagram of a partial structure of the circuit side module of the present invention;

FIG. 5 is a schematic diagram of a partial structure of the circuit side module of the present invention;

FIG. 6 is a schematic diagram of a dual incoming bus side module of the present invention;

fig. 7 is a schematic diagram of an emergency lighting centralized power module according to the present invention.

Wherein, 110, a single incoming line bus side module, 111, a box information submodule, 112, a power distribution calculation submodule, 113, an incoming line description submodule, 114, an incoming line switch model submodule, 115, an electrical fire monitoring submodule, 116, a mutual inductor submodule, 117, an overcurrent protection submodule, 120, a loop side module, 121, a loop matching phase submodule, 122, a switch selection submodule, 123, a reservation submodule, 124, a loop numbering submodule, 125, a lead selection submodule, 126, a loop load submodule, 127, a loop name submodule, 128, a fan control submodule, 129, an intelligent lighting submodule, 130, an electricity meter box module, 140, a box grounding module, 150, a double incoming line bus side module, 151, an incoming line common and standby loop information submodule, 152, a fire power monitoring submodule, 160, an emergency lighting centralized power module, 161, an eight-loop emergency lighting power supply and outgoing line submodule, 162. and an emergency lighting loop sub-module.

Detailed Description

The invention is described in detail below with reference to the figures and specific embodiments. Note that the following description of the embodiments is merely a substantial example, and the present invention is not intended to be limited to the application or the use thereof, and is not limited to the following embodiments.

Examples

A method for generating an electrical system diagram based on Revit, as shown in fig. 1, comprising the steps of:

s1: dividing the electrical system diagram into blocks, and confirming the division of a standard module of the drawing content;

s2: and establishing standardized modules, and confirming sub-modules and sub-module parameters in each standardized module.

In the invention, the divided and obtained standardized modules comprise a single-incoming-line bus side module 110, a double-incoming-line bus side module 150, a loop side module 120, an emergency lighting centralized power supply module 160, an electricity meter box module 130 and a box body grounding module 140.

Specifically, in this embodiment, as shown in fig. 2 to 6, sub-modules and parameter information included in each module are as follows:

the single incoming line bus side module 110 comprises a box body information submodule 111, a power distribution calculation submodule 112, an incoming line description submodule 113, an incoming line switch model submodule 114, an electrical fire monitoring submodule 115, a transformer submodule 116 and an overcurrent protection submodule 117;

the parameters of the box information submodule 111 include bin number, size and installation mode, and the parameters of the distribution calculation submodule 112 include active power Pe, simultaneous coefficient Kc and power factorCalculating current Ic, wherein the parameters of the incoming line description submodule 113 include an incoming line loop number, an incoming line cable model and an incoming line source, the parameters of the incoming line switch model submodule 114 include an incoming line switch model and a corresponding graphic expression, the parameters of the electrical fire monitoring submodule 115 are present or absent, and the mutual inductor is used for realizing the functions of a transformer and a transformerThe parameters of the module 116 include the presence/absence and the type of a mutual inductor, and the parameters of the over-current protection submodule 117 include the presence/absence and the type of an over-current protection device;

the loop side module 120 comprises a loop matching phase submodule 121, a switch type selection submodule 122, a reserved submodule 123, a loop numbering submodule 124, a conducting wire type selection submodule 125, a loop load submodule 126, a loop name submodule 127, a fan control submodule 128 and an intelligent lighting submodule 129;

the parameters of the loop matching phase submodule 121 are power supply phases, the parameters of the switch type selection submodule 122 are model numbers and graphic expressions, the parameters of the reserved submodule 123 are present/absent, the parameters of the loop number submodule 124 are loop numbers, the parameters of the lead type selection submodule 125 are lead model numbers, the parameters of the loop load submodule 126 are load size, the parameters of the loop name submodule 127 are loop names, the parameters of the fan control submodule 128 are present/absent, and the parameters of the intelligent lighting submodule 129 are present/absent;

the electric meter box module 130 is an invariable module, the parameters of the electric meter box module 130 are invariable, the box body grounding module 140 is an invariable module, and the parameters of the electric meter box module 130 are invariable;

the double-incoming-line bus side module 150 comprises an incoming line common loop information submodule 151, an incoming line standby loop information submodule 152, a fire-fighting power supply monitoring submodule 152, a box body information submodule 111, a power distribution calculation submodule 112, an incoming line description submodule 113, an incoming line switch model submodule 114, an electrical fire monitoring submodule 115, a transformer submodule 116 and an overcurrent protection submodule 117;

the parameters of the incoming line common and standby loop information submodule 151 include a common loop number and a standby loop number, and the parameters of the fire power supply monitoring submodule 152 are present or absent;

the emergency lighting centralized power supply module 160 includes a loop phase matching sub-module 121, a switch type selection sub-module 122, an eight-loop emergency lighting power supply and outlet sub-module 161, an emergency lighting loop sub-module 162, a loop number sub-module 124, a lead type selection sub-module 125, a loop load sub-module 126, and a loop name sub-module 127.

In this embodiment, the dual incoming bus side module 150 evolves on the basis of the single incoming bus side module 110, and the emergency lighting centralized power module 160 evolves on the basis of the loop side module 120, so that the loop matching sub-module 121, the switch selection sub-module 122, the loop numbering sub-module 124, the lead selection sub-module 125, the loop load sub-module 126, and the loop name sub-module 127 are retained, and the eight-loop emergency lighting power and outgoing sub-module 161 and the emergency lighting loop sub-module 162 are added. The eight-loop emergency lighting power supply and outgoing line sub-module 161 is an invariable module, and parameters are not modifiable.

S3: and selecting corresponding standardized modules according to the electrical system diagram to be drawn to carry out visibility splicing to form a preliminary electrical system diagram.

According to the system structure requirement of the electrical system diagram to be drawn, a proper standardization module is selected to carry out preliminary splicing of the electrical system diagram. Specifically, in this embodiment, the process of selecting the normalization module is as follows:

s31: selecting one bus side module from the single-incoming-line bus side module 110 and the double-incoming-line bus side module 150 as a bus side module of an electrical system diagram;

s32: at least one module is selected from the loop side module 120 and the emergency lighting centralized power supply module 160 to be used as the loop side module 120 of the electrical system diagram. At least one circuit side module 120 or at least one emergency lighting centralized power module 160 or at least one circuit side module 120 and at least one emergency lighting centralized power module 160 can be selected.

S33: and selecting one electric meter box module 130 and one box body grounding module 140 to be spliced with the modules selected in the S31 and the S32 in a visibility mode to form a preliminary electric system diagram.

S4: carrying out parametric calculation on the preliminary electrical system diagram to obtain a parameter result;

s5: modifying sub-module parameters in the primary system diagram according to the parameter result;

s6: and perfecting the labeled information of the electrical system diagram to generate the electrical system diagram. In this embodiment, the system header and the dotted line division frame of the electrical system diagram are added to perfect the labeling information of the electrical system diagram, and the electrical system diagram is generated.

The above embodiments are merely examples and do not limit the scope of the present invention. These embodiments may be implemented in other various manners, and various omissions, substitutions, and changes may be made without departing from the technical spirit of the present invention.